Characterization of the single-strand-specific BPV-1 origin binding protein, SPSF I, as the HeLa Pur alpha factor

The Molecular Function of PURA and Its Implications in Neurological Diseases

In recent years, genome-wide analyses of patients have resulted in the identification of a number of neurodevelopmental disorders. Several of them are caused by mutations in genes that encode for RNA-binding proteins. One of these genes is PURA, for which in 2014 mutations have been shown to cause the neurodevelopmental disorder PURA syndrome. Besides intellectual disability (ID), patients develop a variety of symptoms, including hypotonia, metabolic abnormalities as well as epileptic seizures. This review aims to provide a comprehensive assessment of research of the last 30 years on PURA and its recently discovered involvement in neuropathological abnormalities. Being a DNA- and RNA-binding protein, PURA has been implicated in transcriptional control as well as in cytoplasmic RNA localization. Molecular interactions are described and rated according to their validation state as physiological targets. This information will be put into perspective with available structural and biophysical insights on PURA’s molecular functions. Two different knock-out mouse models have been reported with partially contradicting observations. They are compared and put into context with cell biological observations and patient-derived information. In addition to PURA syndrome, the PURA protein has been found in pathological, RNA-containing foci of patients with the RNA-repeat expansion diseases such as fragile X-associated tremor ataxia syndrome (FXTAS) and amyotrophic lateral sclerosis (ALS)/fronto-temporal dementia (FTD) spectrum disorder. We discuss the potential role of PURA in these neurodegenerative disorders and existing evidence that PURA might act as a neuroprotective factor. In summary, this review aims at informing researchers as well as clinicians on our current knowledge of PURA’s molecular and cellular functions as well as its implications in very different neuronal disorders.

Proteome Profile of Endogenous Retrotransposon-Associated Complexes in Human Embryonic Stem Cells

Long Interspersed Element-1 (LINE-1 or L1) are transposable elements similar to retroviruses that have existed in the genome of primates for millions of years. They encode two Open Reading Frame (ORF) proteins (ORF1p and ORF2p) that bind L1 RNA to form a ribonucleoprotein (RNP) complex and are required for L1 integration into the host genome. Humans have evolved with L1 and found ways to limit L1 activity. To identify partners of the L1 RNP, previous studies used ectopic expression of L1 ORF1/2p or RNA in various cancer cells, which express low levels of the ORF proteins. Whether naturally occurring L1 RNP interacts with the same proteins in non-cancer cells is unknown. Here, the aim is to examine the natural assembly of endogenous L1 RNPs in normal human cells. L1 elements are expressed in human embryonic stem cells (hESCs), derived from pre-implantation embryos. Therefore, these cells are used to immunoprecipitate ORF1p followed by MS to identify proteins that associate with the naturally-occurring L1 ORF1p. Some of the same proteins as well as unique proteins are found interacting with the endogenous L1 ORF1p complexes. The analysis of ORF1p-associated proteins in hESCs can help address important questions in both retrotransposon biology and the biology of hESCs.

Drosophila Pur-α binds to trinucleotide-repeat containing cellular RNAs and translocates to the early oocyte

Pur-α was identified as a DNA-binding protein with high affinity for the single-stranded PUR-motif (GGN)n. Bound to DNA, Pur-α can both activate and repress transcription. In addition, Pur-α binds to RNA and may participate in nuclear RNA export as well as transport of cytoplasmic neuronal mRNP granules. The heritable trinucleotide-repeat expansion disease Fragile X associated Tremor and Ataxia Syndrome (FXTAS) leads to interaction of Pur-α with mutant, abnormally long r(CGG)n stretches, which appears to titrate the protein away from its physiologic mRNA targets into nuclear RNA-protein aggregates. We examined the function of Drosophila Pur-α and demonstrate that the protein accumulates in the growing oocyte early in oogenesis. Co-purifying proteins reveal that Pur-α is part of transported mRNP complexes, analogous to its reported role in nerve cells. We analyzed the subcellular localization of mutant GFP-Pur-α fusion proteins where either nucleic acid binding or dimerization, or both, were prevented. We propose that association with mRNAs occurs in the nucleus and is required for nuclear export of the complex. Furthermore, efficient translocation into the oocyte also requires RNA binding as well as dimerization. RNA binding assays demonstrate that recombinant Drosophila Pur-α can bind r(CGG) 4 with higher affinity than previously thought. Related sequences, such as r(CAG) 4 and the consensus sequence of the opa-repeat r(CAG) 3CAA, can also associate with Pur-α in vitro and in vivo. The mRNA target spectrum of Pur-α may therefore be larger than previously anticipated.

Regulation of gonadotropin-releasing hormone-1 gene transcription by members of the purine-rich element-binding protein family

Gonadotropin-releasing hormone-1 (GnRH1) controls reproduction by stimulating the release of gonadotropins from the pituitary. To characterize regulatory factors governing GnRH1 gene expression, we employed biochemical and bioinformatics techniques to identify novel GnRH1 promoter-binding proteins from the brain of the cichlid fish, Astatotilapia burtoni (A. burtoni). Using an in vitro DNA-binding assay followed by mass spectrometric peptide mapping, we identified two members of the purine-rich element-binding (Pur) protein family, Puralpha and Purbeta, as candidates for GnRH1 promoter binding and regulation. We found that transcripts for both Puralpha and Purbeta colocalize in GnRH1-expressing neurons in the preoptic area of the hypothalamus in A. burtoni brain. Furthermore, we confirmed in vivo binding of endogenous Puralpha and Purbeta to the upstream region of the GnRH1 gene in A. burtoni brain and mouse neuronal GT1-7 cells. Consistent with the relative promoter occupancy exhibited by endogenous Pur proteins, overexpression of Purbeta, but not Puralpha, significantly downregulated GnRH1 mRNA levels in transiently transfected GT1-7 cells, suggesting that Purbeta acts as a repressor of GnRH1 gene transcription.

Nucleoprotein interactions governing cell type-dependent repression of the mouse smooth muscle alpha-actin promoter by single-stranded DNA-binding proteins Pur alpha and Pur beta

Pur alpha and Pur beta are structurally related single-stranded DNA/RNA-binding proteins implicated in the control of cell growth and differentiation. The goal of this study was to determine whether Pur alpha and Pur beta function in a redundant, distinct, or collaborative manner to suppress smooth muscle alpha-actin gene expression in cell types relevant to wound repair and vascular remodeling. RNA interference-mediated loss-of-function analyses revealed that, although Pur beta was the dominant repressor, the combined action of endogenous Pur alpha and Pur beta was necessary to fully repress the full-length smooth muscle alpha-actin promoter in cultured fibroblasts but to a lesser extent in vascular smooth muscle cells. The activity of a minimal core enhancer containing a truncated 5' Pur repressor binding site was unaffected by knockdown of Pur alpha and/or Pur beta in fibroblasts. Conversely, gain-of-function studies indicated that Pur alpha or Pur beta could each independently repress core smooth muscle alpha-actin enhancer activity albeit in a cell type-dependent fashion. Biochemical analyses indicated that purified recombinant Pur alpha and Pur beta were essentially identical in terms of their binding affinity and specificity for GGN repeat-containing strands of several cis-elements comprising the core enhancer. However, Pur alpha and Pur beta exhibited more distinctive protein interaction profiles when evaluated for binding to enhancer-associated transcription factors in extracts from fibroblasts and vascular smooth muscle cells. These findings support the hypothesis that Pur alpha and Pur beta repress smooth muscle alpha-actin gene transcription by means of DNA strand-selective cis-element binding and cell type-dependent protein-protein interactions.

Mechanism of DNA binding and localized strand separation by Pur alpha and comparison with Pur family member, Pur beta

Pur alpha is a single-stranded (ss) DNA- and RNA-binding protein with three conserved signature repeats that have a specific affinity for guanosine-rich motifs. Pur alpha unwinds a double-stranded oligonucleotide containing purine-rich repeats by maintaining contact with the purine-rich strand and displacing the pyrimidine-rich strand. Mutational analysis indicates that arginine and aromatic residues in the repeat region of Pur alpha are essential for both ss- and duplex DNA binding. Pur alpha binds either linearized or supercoiled plasmid DNA, generating a series of regularly spaced bands in agarose gels. This series is likely due to localized unwinding by quanta of Pur alpha since removal of Pur alpha in the gel eliminates the series and since Pur alpha binding increases the sensitivity of plasmids to reaction with potassium permanganate, a reaction specific for unwound regions. Pur alpha binding to linear duplex DNA creates binding sites for the phage T4 gp32 protein, an ss-DNA binding protein that does not itself bind linearized DNA. In contrast, Pur beta lacking the Pur alpha C-terminal region binds supercoiled DNA but not linearized DNA. Similarly, a C-terminal deletion of Pur alpha can bind supercoiled pMYC7 plasmid, but cannot bind the same linear duplex DNA segment. Therefore, access to linear DNA initially requires C-terminal sequences of Pur alpha.

During differentiation of the monocytic cell line U937, Pur alpha mediates induction of the CD11c beta 2 integrin gene promoter

CD11c is a member of the beta(2) integrin family of adhesion molecules that, together with CD18, forms a heterodimeric receptor on the surface of myeloid, NK, dendritic, and certain leukemic, lymphoma, and activated lymphoid cells. Monocytic differentiation is associated with an induction of both CD11c and CD18 gene expression. The resulting CD11c/CD18 receptor mediates firm adhesion to the vascular endothelium, transendothelial migration, chemotaxis, and phagocytosis. Monocytic differentiation can be mimicked in vitro by treatment of the promonocytic cell line U937 with PMA. Recently, we reported that in U937 cells, expression of the CD11c gene is controlled by an unidentified transcription factor that binds ssDNA. This finding suggested that DNA secondary structure plays an important role in controlling the CD11c gene and prompted us to search for additional ssDNA-binding activities with which this gene interacts. In this study, we report that in U937 cells, expression of the CD11c gene is mediated by the ssDNA-binding protein Puralpha. During PMA-induced differentiation, the ability of Puralpha to activate the CD11c promoter in U937 cells increases, as does that of Sp1. Together, these increases in the functional activity of both Puralpha and Sp1 combine to induce CD11c expression.

Growth inhibition of glioblastoma cells by human Pur(alpha)

Pur(alpha) is a multifunctional DNA- and RNA-binding protein implicated in a variety of biological events including transcription and replication. Further, this protein has the ability to form a complex with several cellular proteins which are important for cell proliferation including the transcription factor, E2F-1. Pur(alpha) has a modular structure highlighted by alternating three basic aromatic class I and two acidic leucine-rich class II repeats in the central region of the protein. Here, we demonstrate that ectopic overexpression of Pur(alpha) suppresses proliferation of a variety of transformed and tumor cells including human glioblastoma. By utilizing various deletion mutants of Pur(alpha) in colony formation assay, we identified the region spanning the first class II repeat (residues 107-131) and the second class I repeat (residues 148-170) of Pur(alpha) which participate in growth inhibitory action of Pur(alpha). Results from protein transduction experiments using the synthetic peptides representing residues 109-131 and 123-154 of Pur(alpha) in fusion with the arginine rich domain of HIV-1 Tat revealed cellular internalization and nuclear appearance of the Tat-Pur(alpha) fusion peptide after 2 h and its detection in nuclei up to 24 h after treatment. Glioblastoma cells treated with Tat-Pur(alpha) (109-131) and Tat-Pur(alpha) (123-154) exhibited 41 and 47% decrease, respectively, in proliferation. Altogether these results illustrate the efficacy of Pur(alpha) in suppressing glioblastoma cell growth and provide evidence for the potential use of this protein and its derivative(s) in blocking proliferation of tumor cells.

Pur alpha protein implicated in dendritic RNA transport interacts with ribosomes in neuronal cytoplasm

We have previously reported that pur alpha, known to be a regulator of DNA replication and transcription, links neural BC1 RNA to microtubules via dendrite-targeting RNA motifs. Here we demonstrate the subcellular localization of pur proteins within the brain. Pur proteins were detected in neurons but not in glia. Immunohistochemical staining was prominent in perikarya and proximal dendrites and also extended into primary dendritic processes, but no significant signals were detected in the distal regions of dendrite. When homogenates of mouse brain were fractionated, pur alpha was most concentrated in the microsomal pellet. Consistently, pur alpha co-fractionated with free polysomes as well as with membrane-bound polysomes and the association with polysomes was mediated by binding ribosomal subunits. Levels of ribosomes with pur alpha progressively increased during postnatal development of the brain.

Single-stranded DNA-binding complex involved in transcriptional regulation of mouse mu-opioid receptor gene

Previously, we reported the presence of dual (distal and proximal) promoters in mouse mu-opioid receptor (mor) gene, with mor transcription in mouse brain predominantly initiated by the proximal promoter. Sp factors, bound to double-stranded (ds) cis-regulatory elements, are critical for proximal promoter activity. Here, we further report that a single-stranded (ss) cis-regulatory element and trans-acting protein factor are also important for proximal promoter activity. A 26-bp mor polypyrimidine/polypurine region (PPy/u) can adopt ss DNA conformation, as demonstrated by S1 nuclease sensitivity. Using electrophoretic mobility shift analysis with nuclear extracts from mor-expressing SH-SY5Y cells, we demonstrate that the sense strand of PPy/u interacts with a major nuclear protein, termed mor polypyrimidine-binding protein (mPy), which is not related to Sp factors. Southwestern blot analysis indicated that mPy protein is approximately 25 kDa in size. Functional analysis suggests that mPy protein can trans-activate mor promoter as well as a heterologous promoter. Moreover, combinatorial activation of ss (mPy) and ds (Sps) DNA binding factors, interacting with an overlapping DNA (PPy/u) region, is necessary for proximal promoter activation. Thus our results suggest that transcription of mouse mor gene is regulated by an interplay of ss and ds DNA binding factors.

The single-stranded DNA- and RNA-binding proteins pur alpha and pur beta link BC1 RNA to microtubules through binding to the dendrite-targeting RNA motifs

Neural BC1 RNA is distributed in neuronal dendrites as RNA-protein complexes (BC1 RNPs) containing Translin. In this study, we demonstrated that the single-stranded DNA- and RNA-binding protein pur alpha and its isoform, pur beta, which have been implicated in control of DNA replication and transcription, linked BC1 RNA to microtubules (MTs). The binding site was within the 5' proximal region of BC1 RNA containing putative dendrite-targeting RNA motifs rich in G and U residues, suggesting that in the cytoplasm of neurons, these nuclear factors are involved in the BC1 RNA transport along dendritic MTs. The pur proteins were not components of BC1 RNP but appeared to associate with MTs in brain cells. Therefore, it is suggested that they may transiently interact with the RNP during transport. In this respect, the interaction of pur proteins with BC1 RNA could be regulated by the Translin present within the RNP, because the binding mode of these two classes of proteins (pur proteins and Translin) to the dendrite-targeting RNA motifs was mutually exclusive. As the motifs are well conserved in microtubule-associated protein 2a/b mRNA as well, the pur proteins may also play a role(s) in the dendritic transport of a subset of mRNAs.

Identification and functional characterization of a member of the PUR-alpha family from Schistosoma mansoni

Schistosoma mansoni p14 gene encodes an eggshell precursor that is expressed only in vitelline cells of mature female worms in response to a male stimulus. The upstream region of the p14 gene contains several potential cis-acting regulatory sequences. We used the upstream region of the p14 gene as bait in a yeast-one-hybrid screen of a S. mansoni cDNA library to identify interacting proteins. We report the identification and characterization of a cDNA (S. mansoni PUR-alpha (SmPUR-alpha)) encoding a protein homologous to single-stranded DNA transcription activator PUR-alpha, that binds to the p14 upstream region and activates transcription of the HIS3 reporter gene in yeast. SmPUR-alpha has a predicted molecular mass of 30 kDa and shares an overall homology of 63% with mammalian PUR-alpha. The DNA binding domain of SmPUR-alpha is highly conserved. We show by gel shift assays that GST-SmPUR-alpha binds to oligonucleotides comprising the p14 upstream region. SmPUR-alpha binds preferentially to single-stranded DNA and also binds RNA. Unlike the mammalian homologue, SmPUR-alpha exhibits little specificity for the PUR element GGn, but shows strong preference for a sequence containing alternating pyrimidines. Our data support that SmPUR-alpha is a single-copy gene and through reverse transcriptase-polymerase chain reaction and in situ hybridization, we show that SmPUR-alpha is constitutively transcribed in many cell types and thus likely plays a role as a general transcription activator in schistosomes.

Puralpha: a multifunctional single-stranded DNA- and RNA-binding protein

Puralpha is a ubiquitous, sequence-specific DNA- and RNA-binding protein which is highly conserved in eukaryotic cells. Puralpha has been implicated in diverse cellular functions, including transcriptional activation and repression, translation and cell growth. Moreover, this protein has been shown to be involved in regulating several human viruses which replicate in the central nervous system (CNS), including human immunodeficiency virus type I (HIV-1) and JC virus (JCV). Puralpha exerts part of its activity by interacting with cellular proteins, including pRb, E2F, cyclin A, Sp1 and members of the Y-box family of proteins, including YB-1 and MSY1, as well as viral proteins such as polyomavirus large T-antigen and HIV-1 Tat. The ability of Puralpha to interact with its target DNA sequence and to associate with several viral and cellular proteins is modulated by RNA. Puralpha has also been shown to be involved in cell growth and proliferation. Its association with pRb, E2F and cyclin A coupled with its fluctuating levels throughout the cell cycle, position Puralpha as a crucial factor in the cell cycle. Moreover, microinjection studies demonstrate that Puralpha causes either a G(1) or G(2) arrest depending on the cell cycle time of injection. The gene encoding Puralpha has been localized to a human locus which is frequently deleted in myelogenous leukemias and other cancers and Puralpha gene deletions have been detected in many cases of lymphoid cancers. The following review details the structural characteristics of Puralpha, its family members and the involvement of this protein in regulating various cellular and viral genes, viral replication and cell growth.

Association of HIV-1 Tat with the cellular protein, Puralpha, is mediated by RNA

The interaction between two regulatory proteins plays a crucial role in the control of several biological events, including gene transcription. In this report, we demonstrate that the interaction between the cellular sequence-specific single-stranded DNA binding protein Puralpha and the HIV type 1 (HIV-1) Tat protein is mediated by specific ribonucleic acids. The region of Tat that is important for its interaction with Puralpha includes the region demonstrated to bind Tat's viral RNA target, TAR. A 10-nucleotide GC-rich consensus sequence identified in RNAs associated with Puralpha derived from human U-87MG cells plays an important role in the Puralpha:Tat interaction as examined by an in vitro reconstitution assay. Furthermore, expression of the Puralpha-associated RNA in these cells enhances transcriptional activation of the HIV-1 promoter by Tat and Puralpha.

Identification of (CAG)(n) and (CGG)(n) repeat-binding proteins, CAGERs expressed in mature neurons of the mouse brain

The trinucleotide repeats (CAG)(n) and (CGG)(n) have been shown to be expanded in responsible genes of several human hereditary neurological disorders. In studies of mice, we previously identified two homologous single-stranded (ss)(CAG) and ss(CGG) repeat-binding proteins, CAGER-1 (44 kDa) and CAGER-2 (40 kDa) (CAG-element-recognizing proteins). The specific binding activities of these proteins were predominantly detected in the mouse brain. We have isolated the cDNAs encoding CAGER-1 and CAGER-2 and found that they were identical to previously reported cDNAs for Puralpha and Purbeta, respectively. Puralpha of 28 kDa was previously identified as a replication-origin-binding protein that is ubiquitously expressed in proliferating cells. We show that the transcripts of CAGERs increase after birth and are detected at high levels in the adult mouse brain but at very low or virtually undetectable levels in other mouse tissues. Biochemical properties and molecular weights are different between CAGERs and Puralpha/beta. Immunostaining with specific antibodies against CAGERs indicates that CAGERs in the mouse brain reside in nonproliferating neurons but not in proliferating glia. We conclude that CAGERs and Puralpha/beta are unrelated proteins, and CAGERs are neuronal single-stranded sequence-binding proteins in the mouse brain. Misassignment of cDNAs is described.

Molecular interactions between single-stranded DNA-binding proteins associated with an essential MCAT element in the mouse smooth muscle alpha-actin promoter

Transcriptional activity of the mouse vascular smooth muscle alpha-actin gene in fibroblasts is regulated, in part, by a 30-base pair asymmetric polypurine-polypyrimidine tract containing an essential MCAT enhancer motif. The double-stranded form of this sequence serves as a binding site for a transcription enhancer factor 1-related protein while the separated single strands interact with two distinct DNA binding activities termed VACssBF1 and 2 (Cogan, J. G., Sun, S., Stoflet, E. S., Schmidt, L. J., Getz, M. J., and Strauch, A. R. (1995) J. Biol. Chem. 270, 11310-11321; Sun, S., Stoflet, E. S., Cogan, J. G., Strauch, A. R., and Getz, M. J. (1995) Mol. Cell. Biol. 15, 2429-2936). VACssBF2 has been recently cloned and shown to consist of two closely related proteins, Puralpha and Purbeta (Kelm, R. J., Elder, P. K., Strauch, A. R., and Getz, M. J. (1997) J. Biol. Chem. 272, 26727-26733). In this study, we demonstrate that Puralpha and Purbeta interact with each other via highly specific protein-protein interactions and bind to the purine-rich strand of the MCAT enhancer in the form of both homo- and heteromeric complexes. Moreover, both Pur proteins interact with MSY1, a VACssBF1-like protein cloned by virtue of its affinity for the pyrimidine-rich strand of the enhancer. Interactions between Puralpha, Purbeta, and MSY1 do not require the participation of DNA. Combinatorial interactions between these three single-stranded DNA-binding proteins may be important in regulating activity of the smooth muscle alpha-actin MCAT enhancer in fibroblasts.

Interaction of the single-stranded DNA-binding protein Puralpha with the human polyomavirus JC virus early protein T-antigen

Large T-antigen, the major regulatory protein encoded by polyomaviruses, including Simian Virus 40 (SV40) and JC virus (JCV), is a multifunctional phosphoprotein that is involved in many viral and cellular events. In addition to its integral role in viral replication and cellular transformation, T-antigen also regulates transcription of both viral and cellular genes. In particular, the viral late promoter has been used as a model for the analysis of T-antigen-mediated transcriptional activation. Earlier studies have demonstrated that the cellular protein Puralpha is able to attenuate the transcriptional activity of JCV T-antigen. We investigated the mechanism whereby Puralpha affects T-antigen function. Co-immunoprecipitation studies demonstrated that Puralpha and JCV T-antigen associate in vivo, and glutathione S-transferase affinity binding assays revealed that these two proteins interact in vitro. Moreover, we localized the sequences of Puralpha that are important for the interaction between Puralpha and JCV T-antigen. In addition, we demonstrated that Puralpha interacts with the SV40 T-antigen. Transient transfection studies demonstrated that Puralpha and JCV T-antigen interact functionally as well. More specifically, Puralpha and a deletion mutant that interacts with T-antigen attenuated T-antigen-mediated transcriptional activation. A Puralpha deletion mutant that is unable to interact with JCV T-antigen, however, was found to be incapable of abrogating JCV T-antigen transactivation. Taken together, these data demonstrate that Puralpha and T-antigen interact both physically and functionally and that this interaction modulates T-antigen-mediated transcriptional activation. The implication of these findings with respect to the cellular role of Puralpha is discussed.

MAGE-11 protein is highly conserved in higher organisms and located predominantly in the nucleus

The MAGE-11 gene belongs to a family whose products were identified first in tumor tissue. The MAGE-11 gene product has not been characterized in detail. We have isolated MAGE-11 cDNA from HeLa cells and confirmed the presence of MAGE-11 protein and of at least 2 other MAGE proteins (MAGE-1 and MAGE-3) in this cell line. Monoclonal antibodies (MAbs), obtained by using a GST-MAGE-11 fusion protein, detect MAGE-11 protein in HeLa cells as a 48 kDa protein. In contrast to other known proteins of the MAGE family, MAGE-11 is found mainly in the nucleus. Immunoprecipitation out of whole-cell extracts from different species reveals that MAGE-11 protein is highly conserved among mammalian cells, suggesting a conserved and important function.

Sequence of cDNAs encoding components of vascular actin single-stranded DNA-binding factor 2 establish identity to Puralpha and Purbeta

Transcriptional repression of the mouse vascular smooth muscle alpha-actin gene in fibroblasts and myoblasts is mediated, in part, by the interaction of two single-stranded DNA binding activities with opposite strands of an essential transcription enhancer factor-1 recognition element (Sun, S., Stoflet, E. S., Cogan, J. G., Strauch, A. R., and Getz, M. J. (1995) Mol. Cell. Biol. 15, 2429-2436). One of these activities, previously designated vascular actin single-stranded DNA-binding factor 2 includes two distinct polypeptides (p44 and p46) which specifically interact with the purine-rich strand of both the enhancer and a related element in a protein coding exon of the gene (Kelm, R. J., Jr., Sun, S., Strauch, A. R., and Getz, M. J. (1996) J. Biol. Chem. 271, 24278-24285). Expression screening of a mouse lung cDNA library with a vascular actin single-stranded DNA-binding factor 2 recognition element has now resulted in the isolation of two distinct cDNA clones that encode p46 and p44. One of these proteins is identical to Puralpha, a retinoblastoma-binding protein previously implicated in both transcriptional activation and DNA replication. The other is a related family member, presumably Purbeta. Comparative band shift and Southwestern blot analyses conducted with cellular p46, p44, and cloned Pur proteins synthesized in vitro and in vivo, establish identity of p46 with Puralpha and p44 with Purbeta. This study implicates Puralpha and/or Purbeta in the control of vascular smooth muscle alpha-actin gene transcription.

Identification of pirin, a novel highly conserved nuclear protein

In this article we describe the molecular cloning of Pirin, a novel highly conserved 32-kDa protein consisting of 290 amino acids. Pirin was isolated by a yeast two-hybrid screen as an interactor of nuclear factor I/CCAAT box transcription factor (NFI/CTF1), which is known to stimulate adenovirus DNA replication and RNA polymerase II-driven transcription. Pirin mRNA is expressed weakly in all human tissues tested. About 15% of all Pirin cDNAs contain a short 34-base pair insertion in their 5'-untranslated regions, indicative of alternative splicing processes. Multiple Pirin transcripts are expressed in skeletal muscle and heart. Western blots and immunoprecipitations employing monoclonal anti-Pirin antibodies reveal that Pirin is a nuclear protein. Moreover, confocal immunofluorescence experiments demonstrate a predominant localization of Pirin within dot-like subnuclear structures. Homology searches using the BLAST algorithm indicate the existence of Pirin homologues in mouse and rat. The N-terminal half of Pirin is significantly conserved between mammals, plants, fungi, and even prokaryotic organisms. Genomic Southern and Western blots demonstrate the presence of Pirin genes and their expression, respectively, in all mammalian cell lines tested. The expression pattern, the concentrated localization in subnuclear structures, and its interaction with NFI/CTF1 in the two-hybrid system classify Pirin as a putative NFI/CTF1 cofactor, which might help to gain new insights in NFI/CTF1 functions.