DNA binding properties of a 110 kDa nucleolar protein.

A single strand specific DNA binding protein was purified to homogeneity from calf thymus nucleoprotein. The monomeric protein is elongated in shape and has a molecular mass of 110 kDa. Since immunocytochemistry revealed that the protein is predominantly located in the nucleolus we refer to it as the 110 kDa nucleolar protein. The protein binds not only to single stranded DNA but also to single stranded RNA, including homopolymeric synthetic RNA. We have used the single stranded DNA binding properties of the 110 kDa protein in model studies to investigate its effects on the configuration of nucleic acid. Our results are: only 50-55 protein molecules are sufficient to saturate all binding sites on the 6408 nucleotides of phage fd DNA; protein binding cause a compaction of single stranded DNA; large nucleoprotein aggregates are formed in the presence of divalent cations; this is due to protein-protein interactions which occur at moderately high concentrations of magnesium-, calcium or manganese ions; the protein induces the reassociation of complementary nucleic acid sequences. We speculate that the 110 kDa protein performs similar reactions in vivo and may have a function related to the processing and packaging of preribosomal RNA.     

Characterization of an adenovirus early protein required for viral DNA replication: A single strand specific DNA binding protein

1. The human adenoviruses types 2, 5 and 12 code for the production of a single strand specific DNA binding protein. The molecular weights of these proteins were 72,000 for types 2 and 5 and 60,000 for type 12. In all three cases proteolytic breakdown fragments of these binding proteins (48,000 MW) were also observed. 2. Analysis of the methionine containing tryptic peptides of these proteins indicate that the types 2 and 5 proteins are similar and clearly distinguishable from the type 12 protein. The peptide maps of these three viral proteins are clearly different from a similar protein found in mock infected cells. 3. Temperature sensitive mutants of type 5 (H5ts125) and type 12(H12tsA275) adenoviruses fail to produce these proteins at the nonpermissive temperature. H5ts125 infected cells grown at the permissive temperature produce a 72,000 MW protein that is thermolabile, for continued binding to DNA, when compared to type 5 wild type adenovirus 72,000 MW protein. An analysis of the phenotype of this adenovirus mutant indicates that it codes for a viral function at early times after infection that is required for viral DNA replication. 4. The in vitro translation of adenovirus specific m-RNA results in the synthesis of a small amount of a 72,000 MW protein that binds to single stranded DNA just like the authentic adenovirus DNA binding proteins produced in infected cells. 5. Adenovirus anti-Tumor antigen (T) anti-serum from hamsters carrying independently derived adenovirus tumors, have been tested for the presence of antibody to purified DNA binding proteins. One antiserum is positive for these antibodies while the other is negative. These results indicate that some, but not all, adenovirus tumors contain large enough levels of the DNA binding proteins to elicit an antibody response. 6. The type 5 adenovirus temperature sensitive mutant, H5ts125, that codes for a thermolabile DNA binding protein, was complemented or suppressed at the nonpermissive temperature, for the replication of adenovirus DNA, by SV40. SV40tsA temperature sensitive mutants, defective in SV40 DNA replication, do not suppress or complement H5ts125 at the nonpermissive temperature.     

Purification and general properties of the DNA-binding protein (P16) from rat liver mitochondria

The mitochondrial DNA-binding protein P16 was isolated from rat liver mitochondrial lysates by affinity chromatography on single strand DNA agarose and separated from DNA in the preparation by alkaline CsCl isopycnic gradients. The top fraction of the gradients contained a single polypeptide species (Mr approximately equal to 15,200) based upon SDS PAGE. Digestion of single strand DNA-bound P16 with proteinase K produced a protease-insensitive, DNA-binding fragment (Mr approximately equal to 6,000) that has been purified by essentially the same procedures used for intact P16. The partial amino acid compositions for P16 and the DNA-binding fragment were obtained by conventional methods. Analysis of subcellular fractions revealed that nearly all of the cellular P16 was located in the mitochondria and that only trace amounts of protein of comparable electrophoretic mobility could be isolated from the nuclear or cytoplasmic fractions. The labeling of P16 with [35S]methionine in primary rat hepatocyte cultures was inhibited by more than 90% by the cytoplasmic translation inhibitor cycloheximide, but unaffected by the mitochondrial-specific agent chloramphenicol. These results indicate that P16 is synthesized on cytoplasmic ribosomes and imported into the mitochondria. The addition of purified P16 to deproteinized mitochondrial DNA resulted in the complete protection of the labeled nascent strands of displacement loops against branch migrational loss during cleavage of parental DNA with SstI, thus providing strong evidence that P16 is the single entity required for this in vitro function. Incubation of P16 with single strand phi X174 DNA, double strand (RF) phi X174 DNA, or Escherichia coli ribosomal RNA and subsequent analysis of the nucleic acid species for bound protein indicated a strong preference of P16 for single strand DNA and no detectable affinity for RNA or double strand DNA. Examination of P16-single strand phi X174 DNA complexes by direct electron microscopy revealed thickened, irregular fibers characteristic of protein-associated single strand DNA.     

The DNA binding properties of the MutL protein isolated from Escherichia coli.

The mutL gene of Escherichia coli, which is involved in the repair of mispaired and unpaired nucleotides in DNA, has been independently cloned and the gene product purified. In addition to restoring methyl-directed DNA repair in extracts prepared from mutL strains, the purified MutL protein binds to both double and single stranded DNA. The affinity constant of MutL for unmethylated single stranded DNA was twice that of its affinity constant for methylated single stranded DNA and methylated or unmethylated double stranded DNA. The binding of MutL to double stranded DNA was not affected by the pattern of DNA methylation or the presence of a MutHLS-repairable lesion.     

Single strand binding protein specific for the polyoma early-coding strand of PEA1 (AP1) regulatory sequence.

We have shown that nuclear and cytosolic proteins from embryonal carcinoma F9 cells are able to bind to the early-coding strand of polyoma enhancer A domain. As demonstrated by mobility shift specific competition experiments, DNase I footprinting, depurination and depyrimidation interference, and proteolytic clipping performed with single stranded oligonucleotides, some of these proteins bind specifically to the early-coding PEA1 (AP1) motif. In addition, 'Southwestern' analysis has made possible the identification of a 46 KD nuclear protein that binds to this sequence. These cellular proteins did not bind to the complementary single strand as demonstrated by mobility shift analysis, nor did they bind to RNA synthesized in vitro by using the complementary strand as template. They were also shown to be different from their corresponding double strand binding factors. This new dimension in the functional flexibility and complexity of the polyoma enhancer suggests new properties of the classic regulating sequences that could provide additional modulation of regulating activities.     

The binding of RecA protein to duplex DNA molecules is directional and is promoted by a single stranded region.

RecA protein from E. coli binds more strongly to single stranded DNA than to duplex molecules. Using duplex DNA that contains single stranded gaps, we have studied the protection by RecA protein at various concentrations, of restriction sites as a function of their distance from the single stranded region. We show that the binding of RecA protein, initiated in the single stranded region, extends progressively along the adjoining duplex in the 5' to 3' direction with respect to the single stranded region. The strand exchange reaction is known to proceed in the same direction.     

TRIP: a novel double stranded RNA binding protein which interacts with the leucine rich repeat of flightless I.

A northwestern screen of a CHO-K1 cell line cDNA library with radiolabelled HIV-1 TAR RNA identified a novel TAR RNA interacting protein, TRIP. The human trip cDNA was also cloned and its expression is induced by phorbol esters. The N-terminus of TRIP shows high homology to the coiled coil domain of FLAP, a protein which binds the leucine-rich repeat (LRR) of Flightless I (FLI) and the interaction of TRIP with the FLI LRR has been confirmed in vitro . TRIP does not bind single stranded DNA or RNA significantly and binds double stranded DNA weakly. In contrast, TRIP binds double stranded RNA with high affinity and two molecules of TRIP bind the TAR stem. The RNA binding domain has been identified and encompasses a lysine-rich motif. A TRIP-GFP fusion is localised in the cytoplasm and excluded from the nucleus. FLI has a C-terminal gelsolin-like domain which binds actin and therefore the association of TRIP with the FLI LRR may provide a link between the actin cytoskeleton and RNA in mammalian cells.     

Sequence-specific single-strand RNA binding protein encoded by the human LINE-1 retrotransposon.

Previous experiments using human teratocarcinoma cells indicated that p40, the protein encoded by the first open reading frame (ORF) of the human LINE-1 (L1Hs) retrotransposon, occurs in a large cytoplasmic ribonucleoprotein complex in direct association with L1Hs RNA(s), the p40 RNP complex. We have now investigated the interaction between partially purified p40 and L1Hs RNA in vitro using an RNA binding assay dependent on co-immunoprecipitation of p40 and bound RNA. These experiments identified two p40 binding sites on the full-length sense strand L1Hs RNA. Both sites are in the second ORF of the 6000 nt RNA: site A between residues 1999 and 2039 and site B between residues 4839 and 4875. The two RNA segments share homologous regions. Experiments involving UV cross-linking followed by immunoprecipitation indicate that p40 in the in vitro complex is directly associated with L1Hs RNA, as it is in the p40 RNP complex found in teratocarcinoma cells. Binding and competition experiments demonstrate that p40 binds to single-stranded RNA containing a p40 binding site, but not to single-stranded or double-stranded DNA, double-stranded RNA or a DNA-RNA hybrid containing a binding site sequence. Thus, p40 appears to be a sequence-specific, single-strand RNA binding protein.     

Determinants for binding of a 40 kDa protein to the leaders of yeast mitochondrial mRNAs.

An abundant yeast mitochondrial 40 kDa protein (p40) binds with high specificity to the 5'-untranslated region of cytochrome c oxidase subunit II (COX2) mRNA. Using mobility shift and competition assays, we show here that purified p40 complexes with the leaders of all eight mitochondrial mRNAs of Saccharomyces cerevisiae. The location of the protein binding site on the different leaders is not conserved with respect to the AUG start codon. In vitro RNA footprint and deletion experiments have been used to define the p40-binding site on the leaders of COX1 and ATP9 mRNAs. Nucleotides at, and near, a single stranded region are protected or exposed for DEPC modification by binding of p40 to these leaders. Removal of this region from the COX1 messenger shows that it is essential for the protein-RNA interaction. While no obvious sequence similarity can be detected between the single stranded regions in different leaders, a nearby helical segment is conserved. A consensus model for p40-RNA interactions is presented and the possible biological function of p40 is discussed.     

Single strand DNA binding of simian virus 40 tumor antigen.

Simian virus 40 T antigen binds to both single and double strand DNA. The single and double strand DNA binding activity of crude T antigen preparations was evaluated by chromatography of the antigen on DNA-cellulose columns. Crude T antigen was retained on both native and denatured DNA-cellulos columns and was eluted from both columns under similar conditions. The interaction of highly purified T antigen with single and double strand DNA was evaluated by competition experiments using a DNA filter binding assay. These experiments showed that T antigen binds preferentially to single strand calf thymus DNA by more than an order of magnitude when compared to double strand calf thymus DNA.     

Characterization of a multisubunit human protein which selectively binds single stranded d(GA)n and d(GT)n sequence repeats in DNA.

A protein which selectively binds d(GA)n and d(GT)n sequence repeats in single stranded DNA has been identified in human fibroblasts. This protein, designated PGB, has been purified at least 500-fold by ammonium sulfate precipitation followed by DEAE-Sepharose column chromatography and affinity chromatography in a column of d(GA)-Sepharose. Electrophoretic mobility shift assays revealed that the PGB protein bound most avidly d(GA)n and d(GT)n tracts of n > 5. It also bound other G-rich DNA sequence repeats, including dGn tracts, with lower affinities. It did not manifest significant binding affinities to single stranded M13 DNA, or to the homopolynucleotides poly dA, poly dC and poly dT, or to various DNA sequence repeats which do not contain G residues, such as d(A-C)n and d(TC)n. It did not bind double stranded d(T-C)n.d(GA)n tracts or other double stranded DNA sequences. In glycerol gradient centrifugation assays the d(GA)n- and the d(GT)n-binding activities cosedimented as a homogeneous protein species having an S20,w = 9.4 +/- 0.7 and an estimated native molecular weight of 190,000 +/- 7,000. UV crosslinking assays revealed that the protein contains 33.6 +/- 2.1 kd subunits which bind d(GA)n and d(GT)n sequences. However, SDS-polyacrylamide gel electrophoresis of the purified protein followed by silver staining indicated that it may also contain other subunits that do not contact the DNA. It is proposed that binding of the PGB protein to single stranded d(GA)n or d(GT)n tracts in double stranded topologically restricted DNA may stimulate strand separation and formation of triple helices or other unusual DNA structures.     

Simian virus 40 large T antigen DNA helicase. Characterization of the ATPase-dependent DNA unwinding activity and its substrate requirements

The ATPase of SV40 large T antigen (T antigen) which is essential for the replication of SV40 minichromosomes was recently shown to be functionally related to a newly discovered DNA helicase activity. The T antigen helicase unwinds DNA duplices of several kilobase pairs in a reaction depending on the presence of hydrolyzable ribo- or deoxyribonucleoside triphosphates. The in vitro rate of movement through duplex DNA was found to be about 100 base pairs/min at 37 degrees C. For DNA unwinding, T antigen requires a 3'-single strand extension of a partially double-stranded substrate and invades the double strand section processively, in a 3' to 5' direction. The minimum length of the single-stranded tail was determined to be less than 5 nucleotides. Unwinding studies in the presence of the Escherichia coli single strand-specific DNA-binding protein and competition experiments indicate that T antigen helicase binds preferentially at the single-stranded/double-stranded DNA junction. This DNA structure is therefore proposed to serve as an entry site for the T antigen helicase. Previously reported data suggest that T antigen is the replicative helicase of the SV40 minichromosome. The results presented here are consistent with these findings and imply that T antigen migrates actively and processively along the template for the leading strand.     

A DNA helicase purified by replication protein A (RPA) affinity chromatography from mouse FM3A cells.

In an effort to identify cellular helicases that mimic the action of SV40 large T-antigen, we performed replication protein A (RPA) affinity chromatography on cell extracts from the mouse mammary carcinoma cell line FM3A. In this way, a novel DNA helicase was isolated and purified to near homogeneity. The most purified fractions showed the presence of two proteins of 28 and 21 kDa. Both proteins interacted with 32P-labeled partially duplex DNA when bound to nitrocellulose membranes and were efficiently UV crosslinked to [alpha-32P]dATP. Helicase activity was strongly stimulated by RPA on DNA substrates containing duplex regions longer than 18 bp. Only weak stimulation was observed in the presence of Escherichia coli single strand DNA binding protein (SSB). The enzyme unwinds DNA in the 5'-3' direction in relation to the strand to which it binds. Only ATP and dATP were efficient as nucleoside triphosphate co-factors, and showed similar Km values of approximately 0.6 mM. The properties of this enzyme suggest that it may take part in reactions mediated by RPA such as those predicted to occur at replication forks or alternatively may function during DNA repair or recombination.