Edward M. Johnson

The HeLa Pur factor binds single-stranded DNA at a specific element conserved in gene flanking regions and origins of DNA replication.

A major site of DNA bending is located 1.6 kb upstream of the P1 transcription start site of the human c-myc gene, near the center of a reported zone of initiation of DNA replication. A repeated, purine-rich element, termed PUR, at the bend site is specifically bound by a protein in HeLa cell nuclear extracts. This protein has specific affinity for the purine-rich single strand of the element. Methylation interference maps a pattern of specific contact points with guanosine bases in a 24-mer oligonucleotide containing the element. UV cross-linking reveals that contact is made by a polypeptide of approximately 28 kDa. The PUR element is present at origins of replication and in gene flanking regions in a variety of eukaryotes from yeasts through humans. The consensus sequence GGNNGAGGGAGARRRR has been derived. This element is present near centers of regions of two mammalian loci (human c-myc and hamster dhfr) recently reported as initiation zones for DNA replication. A 24-mer oligonucleotide representing the hamster dhfr version of the PUR element effectively competes with the human c-myc version for binding to Pur.

An initiation zone of chromosomal DNA replication located upstream of the c-myc gene in proliferating HeLa cells.

Studies on origins of DNA replication in mammalian cells have long been hampered by a lack of methods sensitive enough for the localization of such origins in chromosomal DNA. We have employed a new method for mapping origins, based on polymerase chain reaction amplification of nascent strand segments, to examine replication initiated in vivo near the c-myc gene in human cells. Nascent DNA, pulse-labeled in unsynchronized HeLa cells, was size fractionated and purified by immunoprecipitation with anti-bromodeoxyuridine antibodies. Lengths of the nascent strands that allow polymerase chain reaction amplification were determined by hybridization to probes homologous to amplified segments and used to calculate the position of the origin. We found that DNA replication through the c-myc gene initiates in a zone centered approximately 1.5 kilobases upstream of exon I. Replication proceeds bidirectionally from the origin, as indicated by comparison of hybridization patterns for three amplified segments. The initiation zone includes segments of the c-myc locus previously reported to drive autonomous replication of plasmids in human cells.

Sequence of cDNA comprising the human pur gene and sequence-specific single-stranded-DNA-binding properties of the encoded protein.

The human Pur factor binds strongly to a sequence element repeated within zones of initiation of DNA replication in several eukaryotic cells. The protein binds preferentially to the purine-rich single strand of this element, PUR. We report here the cloning and sequencing of a cDNA encoding a protein with strong affinity for the PUR element. Analysis with a series of mutated oligonucleotides defines a minimal single-stranded DNA Pur-binding element. The expressed Pur open reading frame encodes a protein of 322 amino acids. This protein, Pur alpha, contains three repeats of a consensus motif of 23 amino acids and two repeats of a second consensus motif of 26 amino acids. Near its carboxy terminus, the protein possesses an amphipathic alpha-helix and a glutamine-rich domain. The repeat region of Pur cDNA is homologous to multiple mRNA species in each of several human cell lines and tissues. The HeLa cDNA library also includes a clone encoding a related gene, Pur beta, containing a version of the 23-amino-acid consensus motif similar, but not identical, to those in Pur alpha. Results indicate a novel type of modular protein with capacity to bind repeated elements in single-stranded DNA.

Purα Is Essential for Postnatal Brain Development and Developmentally Coupled Cellular Proliferation As Revealed by Genetic Inactivation in the Mouse

ABSTRACT The single-stranded DNA- and RNA-binding protein, Purα, has been implicated in many biological processes, including control of transcription of multiple genes, initiation of DNA replication, and RNA transport and translation. Deletions of the PURA gene are frequent in acute myeloid leukemia. Mice with targeted disruption of the PURA gene in both alleles appear normal at birth, but at 2 weeks of age, they develop neurological problems manifest by severe tremor and spontaneous seizures and they die by 4 weeks. There are severely lower numbers of neurons in regions of the hippocampus and cerebellum of PURA−/− mice versus those of age-matched +/+ littermates, and lamination of these regions is aberrant at time of death. Immunohistochemical analysis of MCM7, a protein marker for DNA replication, reveals a lack of proliferation of precursor cells in these regions in the PURA−/− mice. Levels of proliferation were also absent or low in several other tissues of the PURA−/− mice, including those of myeloid lineage, whereas those of PURA+/− mice were intermediate. Evaluation of brain sections indicates a reduction in myelin and glial fibrillary acidic protein labeling in oligodendrocytes and astrocytes, respectively, indicating pathological development of these cells. At postnatal day 5, a critical time for cerebellar development, Purα and Cdk5 were both at peak levels in bodies and dendrites of Purkinje cells of PURA+/+ mice, but both were absent in dendrites of PURA−/− mice. Purα and Cdk5 can be coimmunoprecipitated from brain lysates of PURA+/+ mice. Immunohistochemical studies reveal a dramatic reduction in the level of both phosphorylated and nonphosphorylated neurofilaments in dendrites of the Purkinje cell layer and of synapse formation in the hippocampus. Overall results are consistent with a role for Purα in developmentally timed DNA replication in specific cell types and also point to a newly emerging role in compartmentalized RNA transport and translation in neuronal dendrites.

Association of human Pur alpha with the retinoblastoma protein, Rb, regulates binding to the single-stranded DNA Pur alpha recognition element.

The retinoblastoma protein, Rb, is detected in extracts of monkey CV-1 cells complexed with Purα, a sequence-specific single-stranded DNA-binding protein implicated in control of gene transcription and DNA replication. These complexes can be immunoextracted from cell lysates using monoclonal antibodies to either Purα or Rb. The Purα•Rb complexes contain a form of Purα with extensive post-synthetic modification, as demonstrated following expression of Purα cDNA fused to a 9-amino acid epitope tag. Human Purα, expressed as a glutathione S-transferase fusion protein, specifically binds to the hypophosphorylated form of Rb with an affinity as high as that of SV40 large T-antigen. In the absence of DNA, glutathione S-transferase-Purα binds to p56RB, an NH2-terminal-truncated Rb protein purified from Escherichia coli, containing the T-antigen binding domain, to form multimeric complexes. The single-stranded DNA Purα recognition element disrupts these complexes. Conversely, high concentrations of p56RB prevent Purα binding to DNA. Through use of a series of deletion mutants, the DNA binding activity of Purα is localized to a series of modular amino acid repeats. Rb binding involves a Purα region with limited homology to the Rb-binding region of SV40 large T-antigen. Binding of Purα to p56RB, the COOH-terminal portion of Rb, is inhibited by a synthetic peptide containing the T-antigen Rb-binding motif.

Role of Purα in targeting mRNA to sites of translation in hippocampal neuronal dendrites

Using genetic inactivation in the mouse, PURA, encoding Purα, is demonstrated to be essential for developmentally‐timed dendrite formation in the cerebellum and hippocampus. Comparison of RNA species bound by Purα prompts the hypothesis that Purα functions with non‐coding RNA in transport of certain mRNA molecules to sites of translation in dendrites. Purα binds to human BC200 RNA, implicated in dendritic targeting, and this has homologies to 7SL RNA, implicated in compartmentalized translation. Results using hippocampal rat neurons in situ show that Purα binds to BC1 RNA, implicated in dendritic targeting as a mouse counterpart of BC200, and to mRNA molecules translated in dendrites; Purα is specifically located in dendrites, where it is colocalized with Map2, but not in axons, where it fails to colocalize with Ankyrin G. Purα and Staufen are colocalized at dendritic sites of mRNA translation. Microtubule disruptors inhibit Purα dendritic targeting and allow its mislocalization to axons. Using mouse brain, double‐RNA immunoprecipitation places Purα together with Staufen or FMRP on BC1 RNA and specific mRNA species in vivo. These results help define a mechanism by which Purα targets specific mRNA molecules to sites of dendritic translation.

Isolation and Characterization of a Novel H1.2 Complex That Acts as a Repressor of p53-mediated Transcription

Linker histone H1 has been generally viewed as a global repressor of transcription by preventing the access of transcription factors to sites in chromatin. However, recent studies suggest that H1 can interact with other regulatory factors for its action as a negative modulator of specific genes. To investigate these aspects, we established a human cell line expressing H1.2, one of the H1 subtypes, for the purification of H1-interacting proteins. Our results showed that H1.2 can stably associate with sets of cofactors and ribosomal proteins that can significantly repress p53-dependent, p300-mediated chromatin transcription. This repressive action of H1.2 complex involves direct interaction of H1.2 with p53, which in turn blocks p300-mediated acetylation of chromatin. YB1 and PURα, two factors present in the H1.2 complex, together with H1.2 can closely recapitulate the repressive action of the entire H1.2 complex in transcription. Chromatin immunoprecipitation and RNA interference analyses further confirmed that the recruitment of YB1, PURα, and H1.2 to the p53 target gene Bax is required for repression of p53-induced transcription. Therefore, these results reveal a previously unrecognized function of H1 as a transcriptional repressor as well as the underlying mechanism involving specific sets of factors in this repression process.

Multiple roles for Pur-α in cellular and viral regulation

Pur-alpha is a ubiquitous multifunctional protein that is strongly conserved throughout evolution, binds to both DNA and RNA and functions in the initiation of DNA replication, control of transcription and mRNA translation. In addition, it binds to several cellular regulatory proteins including the retinoblastoma protein, E2F-1, Sp1, YB-1, cyclin T1/Cdk9 and cyclin A/Cdk2. These observations and functional studies provide evidence that Purα is a major player in the regulation of the cell cycle and oncogenic transformation. Purα also binds to viral proteins such as the large T-antigen of JC virus (JCV) and the Tat protein of human immunodeficiency virus-1 (HIV-1) and plays a role in the cross-communication of these viruses in the opportunistic polyomavirus JC (JCV) brain infection, progressive multifocal leukoencephalopathy (PML). The creation of transgenic mice with inactivation of the PURA gene that encodes Purα has revealed that Purα is critical for postnatal brain development and has unraveled an essential role of Purα in the transport of specific mRNAs to the dendrites and the establishment of the postsynaptic compartment in the developing neurons. Finally, the availability of cell cultures from the PURA knockout mice has allowed studies that have unraveled a role for Purα in DNA repair.

Regulation of myelin basic protein gene transcription by Sp1 and Purα: Evidence for association of Sp1 and Purα in brain

Direct interaction between transcription factors may provide a mechanism for the regulatory function of these proteins on transcription of the responsive genes. These interactions may be facilitated if the target DNA sequences for the participant regulatory proteins are overlapped or positioned in close proximity to each other within the promoter of the responsive genes. In earlier studies, we identified a cellular protein, named Purα, which upon binding to the MB1 regulatory DNA sequence of the myelin basic protein (MBP) gene, stimulates its transcription in central nervous system (CNS) cells. Here, we provide evidence for binding of the ubiquitous DNA binding transcription factor, Sp1, to the MB1 DNA motif at the region that partially overlaps with the Purα binding site. We demonstrate that binding of Purα to its target sequence is enhanced by inclusion of Sp1 in the binding reaction. Under this condition, binding of Sp1 to the MB1 regulatory sequence remained fairly unchanged, and no evidence for the formation of Purα:MB1:Sp1 was observed. This observation suggests that transient interaction of Purα and Sp1 may result in stable association of Purα and the MB1 element. In support of this notion, results from immunoprecipitation/Western blot studies have established association of Purα and Sp1 in nuclear extracts from mouse brain. Of interest, Purα appears to bind to the phosphorylated form of Sp1 which is developmentally regulated and that coincides with the periods when MBP gene expression is at its maximum level. Results from cotransfection studies revealed that ectopic expression of Purα and Sp1 synergistically stimulates MBP promoter activity in CNS cells. The importance of these findings in stage‐specific expression of MBP during brain development is discussed. J. Cell. Physiol. 181:160–168, 1999.

THE SINGLE-STRANDED DNA BINDING PROTEIN, PUR-ALPHA , BINDS HIV-1 TAR RNA AND ACTIVATES HIV-1 TRANSCRIPTION

Previous studies indicate that the bulge and loop domains of TAR, the HIV-1 RNA regulatory element, bind viral and cellular factors that are critical for efficient transcription of the HIV-1 genome. In this report, we demonstrate that the cellular protein, Pur-alpha, a previously characterized sequence specific, single-stranded DNA binding protein, binds to HIV-1 TAR RNA in a specific manner as demonstrated by competition analysis. Pur-alpha binds to the greatest extent to wild-type TAR RNA, and it appears the primary sequence, as well as the secondary structure and its overall stability contribute to this binding. Results from gel shift analysis using mutant Pur-alpha proteins indicate that amino acids 55-85, which contain the first of three basic aromatic repeats, are important for its binding to TAR RNA. Overexpression of Pur-alpha in a glial cell line increased transcription of HIV-1 LTR by a TAR dependent mechanism. The potential contribution by Pur-alpha to HIV-1 expression in relation to basal transcription by cellular factors is discussed.